Mastering Microcontroller: Timers, Pwm, Can, Low Power(Mcu2) (updated 3/2023) - Printable Version +- Softwarez.Info - Software's World! (https://softwarez.info) +-- Forum: Library Zone (https://softwarez.info/Forum-Library-Zone) +--- Forum: Video Tutorials (https://softwarez.info/Forum-Video-Tutorials) +--- Thread: Mastering Microcontroller: Timers, Pwm, Can, Low Power(Mcu2) (updated 3/2023) (/Thread-Mastering-Microcontroller-Timers-Pwm-Can-Low-Power-Mcu2-updated-3-2023) |
Mastering Microcontroller: Timers, Pwm, Can, Low Power(Mcu2) (updated 3/2023) - AD-TEAM - 09-17-2024 Mastering Microcontroller: Timers, Pwm, Can, Low Power(Mcu2) Last updated 3/2023 MP4 | Video: h264, 1280x720 | Audio: AAC, 44.1 KHz Language: English | Size: 14.31 GB | Duration: 21h 24m Learn STM32 Timers, CAN, RTC, PWM, Low Power embedded systems and program them using STM32 Device HAL APIs step by step.
[b]What you'll learn[/b] You will learn from scratch about STM32 Timers : Basic and General Purpose Timers Understand General purpose timer's Input capture and Output compare unit handling and Exercises Handling of Timer interrupts : Time base interrupts, capture interrupts, compare interrupts You will learn from scratch CAN Protocol, CAN Signalling, CAN Transceivers , Bus Access procedures Understand CAN LOOPBACK mode, SILENT mode and NORMAL mode Understand about CAN filtering Learn about CAN interrupts CAN Peripheral programming using STM32 device HAL drivers You will master Low power modes of the MCU : SLEEP,STOP and STANDBY You will understand different power domains of the MCU : VDD domain, 1.2V domain, backup domain Understand Microcontroller Wakeup Procedures using : RTC, wakeup pins,EXTI,etc. You will master RTC Features : CALENDAR, ALARM , TIME STAMP,WAKEUP UNIT RTC interrupts and wake up procedures Mastering Microcontroller Clocks Handling : HSE,HSI,LSE,LSI,PLL Understand phase locked loop (PLL) programming Learn PWM mode and Master through step by step code exercises You should be able to quickly develop applications which involves STM32 Device HAL layer [b]Requirements[/b] Basic knowledge of C Programming and Microcontroller could be added advantage but not mandatory [b]Description[/b] Update: English closed captions have been added, transcript availableCourse code: MCU2>>Welcome to the course which teaches you advanced Micro-controller programming. In this course you are going to learn and master Timers , PWM, CAN, RTC, Low Power modes of STM32F4x Micro-controller with step by step guidance. Highly recommended if you are seeking a career in the domain of Embedded software. < Overview Section 1: Introduction Lecture 1 what are we going to do in this course ? Lecture 2 Important Note Lecture 3 Source Code and Slides Lecture 4 Rating and Review Section 2: Development board details Lecture 5 Note for the students Lecture 6 About the development board used in this course Lecture 7 Board Details and Locating Documents Lecture 8 ST-Link Driver Installation Lecture 9 ST Link Firmware Upgrade Section 3: Hardware/Software Requirements Lecture 10 Hardware/Software Requirements Section 4: Installing OpenSTM32 System-Workbench Lecture 11 Note for the students Lecture 12 Downloading and Installing OpenSTM32 System-Workbench Lecture 13 Installing OpenSTM32 System-Workbench Lecture 14 STM32 CUBE mx installation Section 5: STM32 HAL and Project Architecture Lecture 15 Introduction to STM32 Cube Project Architecture Lecture 16 Creating and Importing Project into OpenSTM32 System Workbench - Part1 Lecture 17 Understanding Project Hierarchy Lecture 18 Project Layers Interaction Lecture 19 STM32 Cube framework program flow-1 Lecture 20 STM32 Cube framework program flow-2 Lecture 21 HAL_Init() Lecture 22 Understanding main.c msp.c and it.c Lecture 23 Peripheral Handle Structure Lecture 24 Linking Handle Structure and Peripheral Lecture 25 STM32 HAL Header File Hierarchy Section 6: Understanding STM32 HAL program flow with UART exercise Lecture 26 Importing Source Codes Lecture 27 Project Creation Lecture 28 Low level Processor specific hardware initialization: Part 1 Lecture 29 Low level Processor specific hardware initialization: Part 2 Lecture 30 Low level Processor specific hardware initialization: Part 3 Lecture 31 Peripheral High Level Initialization Lecture 32 Peripheral Low Level Initialization Lecture 33 Peripheral Low Level Initialization : configuring Pin Packs Lecture 34 Peripheral Low Level Initialization : Alternate function settings Lecture 35 Peripheral Low Level Initialization : IRQ settings Lecture 36 STM32 HAL Peripheral data handling APIs Lecture 37 UART Data TXing : Part 1 Lecture 38 UART Data TXing : Part 2 Lecture 39 UART Data RXing: Intro Lecture 40 Implementing UART DATA RXing in Polling mode Lecture 41 UART Data RXing in Interrupt Mode : Part 1 Lecture 42 UART Data RXing in Interrupt Mode : Part 2 Lecture 43 UART Data RXing in Interrupt Mode : Part 3 Lecture 44 UART Data RXing in Interrupt Mode : Part 4 Section 7: Clocks and PLL Programming Lecture 45 Introduction to different clock sources of the microcontroller Lecture 46 Understanding methods to configure the SYSCLK Lecture 47 Exploring clock handling APIs in RCC driver files Lecture 48 Exercise : OSC Init and HSE bypass Lecture 49 Exercise : Clock init implementation Lecture 50 Exercise : SYSTICK configuration and summary Lecture 51 Exercise : Testing Lecture 52 Understanding HSI calibration Lecture 53 PLL introduction and working principle Lecture 54 Exercise : PLL Configuration via HSI Part 1 Lecture 55 Exercise : PLL Configuration via HSI Part 2 Lecture 56 Exercise : PLL Configuration via HSE Lecture 57 Exercise : PLL Configuration for 180MHz Lecture 58 Exercise : PLL Configuration for 180MHz implementation Section 8: Timers Lecture 59 Introduction to Timers Lecture 60 Types of Timers Lecture 61 Timer Availability in STM32 MCUs Lecture 62 Timer Availability in STM32 MCUs : Summary Lecture 63 STM32 Basic Timer Assembly Lecture 64 Timer Exercise : Project creation Lecture 65 Timer Exercise : Understanding Timer Clock (TIMx_CLK) Lecture 66 Timer Exercise : Understanding Prescaler and Period(ARR) Lecture 67 Timer Exercise : Period Value Calculation Lecture 68 Timer Exercise : MSP Init Implementation Lecture 69 Timer Exercise : Test Lecture 70 Timer Exercise : Interrupt Mode Lecture 71 Timer Exercise : 10 Micro timer base generation Section 9: General Purpose Timer: Input Capture Unit Lecture 72 Timer with input capture block Lecture 73 Input Capture Exercise : working principle Lecture 74 Input Capture Exercise : time base init Lecture 75 Input Capture Exercise : Channel Configuration Lecture 76 Input Capture Exercise : Channel Configuration Coding Lecture 77 LSE Configuration Lecture 78 Testing of LSE on MCO1 Pin Lecture 79 Timer Input Capture Callback Implementation Lecture 80 Input Capture Exercise : Testing Lecture 81 Input Capture Exercise : Update on HSE Lecture 82 Input Capture Exercise : with 4Mhz external signal Lecture 83 Input Capture Exercise : with 50KHz external signal Section 10: Timer's Output Compare unit Lecture 84 Timer Output compare Introduction Lecture 85 Output Compare Exercise : Project Creation Lecture 86 Output Compare Exercise Coding : Part 1 Lecture 87 Output Compare Exercise Coding : Part 2 Lecture 88 Output Compare Exercise Coding : Part 3 Lecture 89 Output Compare Exercise Coding : Part 4 Lecture 90 Output Compare Assignment Section 11: PWM Lecture 91 PWM Introduction Lecture 92 PWM Exercise : Part 1 Lecture 93 PWM Exercise : Part 2 Lecture 94 PWM Exercise : Part 3 Lecture 95 PWM Exercise : Part 4 Lecture 96 PWM Exercise : Part 5 Lecture 97 PWM Exercise : Part 6 Lecture 98 PWM Exercise : Part 7 Lecture 99 LED brightness control using PWM signal: Part 1 Lecture 100 LED brightness control using PWM signal: Part 2 Section 12: Controller Area Network Fundamentals Lecture 101 CAN section introduction Lecture 102 Introduction to CAN Lecture 103 CAN's most attractive features Lecture 104 Summary of CAN features Lecture 105 Understanding a CAN and its parts Lecture 106 CAN single ended signals Vs Differential signal Lecture 107 Understanding CAN differential signals Lecture 108 CAN Dominant and Recessive Signal states Lecture 109 CAN signalling summary Section 13: CAN frame formats Lecture 110 CAN Message format explanation : Arbitration field Lecture 111 Standard CAN Vs Extended CAN Lecture 112 CAN Message format explanation : ACK bit Lecture 113 ACK Summary Lecture 114 CAN Message format explanation : EOF, IFS and SOF Lecture 115 CAN remote frame Section 14: CAN Bus Arbitration Lecture 116 Understanding CAN bit wise arbitration Section 15: STM32 bxCAN Lecture 117 STM32 bxCAN introdcution Lecture 118 STM32 bxCAN block diagram Lecture 119 STM32 bxCAN self test modes Lecture 120 Exercise : CAN loop back mode : Project Creation Lecture 121 CAN bit timing calculation Lecture 122 Exercise : CAN loop back mode : Coding init function Lecture 123 Exploring bxCAN TX path Lecture 124 Exercise : CAN loop back mode : Coding Tx function Lecture 125 understanding bxCAN operating modes Lecture 126 Exercise : CAN loop back mode : MSP code implementation Lecture 127 CAN loopback connection details Lecture 128 Exercise : CAN loop back mode : Testing and Protocol decoding Lecture 129 STM32 bxCAN RX block diagram and acceptance filters Section 16: bxCAN Frame filtering Lecture 130 Understanding bxCAN acceptance filtering with examples Lecture 131 Exploring filtering data structures Lecture 132 Exercise : CAN loop back mode : Coding RX function Lecture 133 Exercise : CAN filter config implementation and testing TX-RX Section 17: CAN interrupts Lecture 134 Understanding STM32 bxCAN Interrupt requests (IRQs) Lecture 135 CAN LOOPBACK interrupt mode implementation Part -1 Lecture 136 CAN LOOPBACK interrupt mode implementation Part -2 Section 18: CAN normal mode and exercise Lecture 137 Exercise : CAN Normal Node Introduction - Part-1 Lecture 138 Exercise : CAN Normal Node Project Creation- Part-2 Lecture 139 Exercise : CAN Normal Node Code Implementation - Part-3 Lecture 140 Exercise : CAN Normal Node Code Implementation - Part-4 Lecture 141 Exercise : CAN Normal Node Code Implementation - Part-5 Lecture 142 Exercise : CAN Normal Node Testing TX - Part-6 Lecture 143 Exercise : CAN Normal Node Testing TX - Part-7 Lecture 144 Exercise : CAN Normal Node RX Code implementation- Part-8 Lecture 145 Exercise : CAN Normal Node RX Code implementation- Part-9 Lecture 146 Exercise : CAN Normal Node Sending Remote Frame Part-10 Lecture 147 Exercise : CAN Normal Node Testing- Part-11 Lecture 148 Exercise : CAN Normal Node Testing TX at 1Mbit/sec - Part-12 Lecture 149 Exercise : CAN Normal Configuring acceptance filtering - Part-13 Lecture 150 Exercise : CAN Normal Configuring acceptance filtering - Part-14 Section 19: Low Power Modes Lecture 151 Section Introduction Lecture 152 MCU low power modes introduction Lecture 153 Processor specific low power modes Lecture 154 Entering normal and deep sleep modes Lecture 155 Entering sleep mode using SLEEPONEXIT feature Lecture 156 Exercise : Usage of SLEEPONEXIT feature Lecture 157 waking up from SLEEPONEXIT feature Lecture 158 Exercise : test SLEEPONEXIT feature -creating a project Lecture 159 Exercise : Implementation and current measurement without SLEEPONEXIT feature Lecture 160 Current measurement with SLEEPONEXIT feature Lecture 161 SLEEPONEXIT Exercise summary Section 20: Current reduction tips and tricks Lecture 162 Tips to reduce current consumption Lecture 163 Current measurement with increased HCLK frequency Lecture 164 Current measurement with increased UART baudrate Lecture 165 Clock gating and RCC Low power register settings Lecture 166 IO analog mode and effect on current consumption Lecture 167 Current measurement in IO analog mode Section 21: WFI and WFE Lecture 168 Understanding WFI instruction Lecture 169 WFI Exercise Introduction Lecture 170 WFI Exercise Implementation Lecture 171 Understanding WFE and event register of ARM Cortex Mx processor Lecture 172 WFE wake-up behavior and Comparison with WFI Lecture 173 WFE exercise introduction Lecture 174 WFE project explanation Lecture 175 Generating Peripheral events in STM32 MCU Lecture 176 WFE project implementation-Part1 Lecture 177 WFE project implementation-Part2 Lecture 178 Difference and similarity between WFI and WFE Lecture 179 When to use WFE and WFI ? Section 22: STM32 Low Power modes and Voltage domains Lecture 180 MCU specific low power modes Lecture 181 STM32 MCU voltage domains Section 23: STM32 Voltage Regulator Lecture 182 STM32 voltage regulator and its modes Lecture 183 Voltage regulator Over Drive and Power Down mode Section 24: Current Measurement and datasheet comparison : RUN Mode Lecture 184 Current measurement with core-mark in Run mode-Part1 Lecture 185 Current measurement with core-mark in Run mode-Part2 Lecture 186 Run mode current measurement + HCLK180MHz+ all peripherals enabled Lecture 187 Run mode current measurement + HCLK180MHz + all peripherals enabled + ART Section 25: Current Measurement and datasheet comparison : SLEEP Mode Lecture 188 SLEEP mode current measurement Lecture 189 SLEEP mode and Voltage regulator settings to save current Section 26: Current Measurement and datasheet comparison : STOP Mode Lecture 190 STOP mode and wake-up latency Lecture 191 STOP mode current measurement Lecture 192 Microcontroller wake-up Pins discussion Section 27: STM32 BACKUP SRAM and STANDBY MODE effect Lecture 193 Understanding STM32 BACKUP SRAM Lecture 194 Different types of MCU resets Lecture 195 BACKUP SRAM exercise Intro Lecture 196 Backup SRAM Exercise implementation part 1 Lecture 197 Backup SRAM Exercise implementation part 2 Section 28: RTC and RTC Calendar Block Lecture 198 RTC Introduction Lecture 199 RTC BCD programming example Lecture 200 RTC block diagram and RTC Clock selection Lecture 201 RTC and STM32 device HAL APIs explanation Lecture 202 Exercise : RTC Calendar Part-1 Lecture 203 Exercise : RTC Calendar Part-2 Lecture 204 Exercise : RTC Calendar Part-3 Lecture 205 Exercise : RTC Calendar Part-4 Lecture 206 Exercise : RTC Calendar Testing Lecture 207 Exercise : RTC Calendar Testing with system reset and STANDBY exit Section 29: RTC Alarm Lecture 208 RTC Alarm Introduction Lecture 209 STM32 CUBE APIs for RTC Alarm Handling Section 30: RTC Interrupts Lecture 210 RTC Interrupts and IRQ numbers Lecture 211 RTC Interrupts Summary Section 31: RTC Alarm Exercises Lecture 212 RTC Alarm Exercise-1 Lecture 213 RTC Alarm Exercise-1 Testing Lecture 214 RTC Alarm Exercise-2 Lecture 215 RTC Alarm Exercise-2 Testing Lecture 216 RTC Alarm Exercise-3 Lecture 217 RTC Alarm Exercise-4 Lecture 218 BONUS LECTURE Professionals interested in exploring Embedded systems,Anyone who wants to start career in Embedded Systems,Anyone who wants to learn Microcontroller programming in depth,Students in the domain of Embedded Systems |